NEW PROGRESS IN THE FIELD OF EXTRAORDINARY ENVIRONMENTAL MECHANICS——REVIEW OF THE CHINESE JOURNAL OF THEORETICAL AND APPLIED MECHANICS SYMPOSIUM ON EXTREME MECHANICS

Jiang Zonglin; Liu Junli; Yuan Chaokai; Chen Haixuan; Lu Xiyun

doi:10.6052/0459-1879-20-442

Volume 53 Issue 2

Feb. 2021

Turn off MathJax

Article Contents

Abstract

References

Chinese Journal of Theoretical and Applied Mechanics > 2021 > 53(2): 589-599. > DOI: 10.6052/0459-1879-20-442 CSTR: 32045.14.0459-1879-20-442

Jiang Zonglin, Liu Junli, Yuan Chaokai, Chen Haixuan, Lu Xiyun. NEW PROGRESS IN THE FIELD OF EXTRAORDINARY ENVIRONMENTAL MECHANICS——REVIEW OF THE CHINESE JOURNAL OF THEORETICAL AND APPLIED MECHANICS SYMPOSIUM ON EXTREME MECHANICS[J]. Chinese Journal of Theoretical and Applied Mechanics, 2021, 53(2): 589-599. DOI: 10.6052/0459-1879-20-442

Citation:

PDF (303 KB)

NEW PROGRESS IN THE FIELD OF EXTRAORDINARY ENVIRONMENTAL MECHANICS——REVIEW OF THE CHINESE JOURNAL OF THEORETICAL AND APPLIED MECHANICS SYMPOSIUM ON EXTREME MECHANICS

Jiang Zonglin^*,
Liu Junli^†,2), ,,
Yuan Chaokai^*,3), ,,
Chen Haixuan^†,
Lu Xiyun^**

^*State Key Laboratory of High-Temperature Gas Dynamics, Institute of Mechanics, Chinese Academy of Sciences, Beijing 100190, China
^†Periodical Publishing House of Chinese Journal of Theoretical and Applied Mechanics, Beijing 100190, China
^**Department of Modern Mechanics, University of Science and Technology of China, Hefei 230027, China

Received Date: December 20, 2020

Graphical Abstract

Abstract

Abstract

This article introduces the background knowledge of extraordinary environmental mechanics and reviews the frontier progress in the field of extreme mechanics that was reported on the Chinese Journal of Theoretical and Applied Mechanics (CJTAM) symposium. This article focuses on research directions that are critical for the national security, such as the deep sea, deep space and high temperature and hypersonic flow, and introduces the significant achievements and the latest research progress in the field of extraordinary environmental mechanics. Through this conference, the editorial department of CJTAM is exploring a new communication mode, which can timely convey the cutting-edge and groundbreaking achievements to researchers, thus supporting the research and development in related engineering and technology fields. This article also summarizes the research fields involved in the symposium, hoping to promote research and communication within the field of extraordinary environmental mechanics.

FullText(HTML)

References (61)

References

[1]	郑晓静. 关于极端力学. 力学学报, 2019,51(4):1266-1272. (Zheng Xiaojing. Extreme mechanics. Chinese Journal of Theoretical and Applied Mechanics. 2019,51(4):1266-1272 (in Chinese))
[2]	Gao FP, Wang N, Zhao B. Ultimate bearing capacity of a pipeline on clayey soils: Slip-line field solution and FEM simulation. Ocean Engineering, 2013,73:159-167
[3]	刘俊, 高福平. 近壁面柱体涡激振动的迟滞效应. 力学学报, 2019,51(6):1630-1640 (Liu Jun, Gao Fuping. Hysteresis in vortex-induced vibrations of a near-wall cylinder. Chinese Journal of Theoretical and Applied Mechanics. 2019,51(6):1630-1640 (in Chinese))
[4]	Gao FP. Flow-pipe-soil coupling mechanisms and predictions for submarine pipeline instability. Journal of Hydrodynamics, 2017,29(5):763-773
[5]	Shi YM, Gao FP. Lateral instability and tunnel erosion of a submarine pipeline: competition mechanism. Bulletin of Engineering Geology and the Environment, 2018,77(3):1069-1080
[6]	Tan DL, Zhou JF, Wang X. et al. Combined effects of topography and bottom friction on shoaling internal solitary waves in the South China Sea. Applied Mathematics and Mechanics, 2019,40(4):421-434
[7]	Tan DL, Zhou JF, Wang X. Fission law of solitary waves propagating over sharply variable topography. Journal of Hydrodynamics, 2020,32(4):727-734
[8]	Wang X, Zhou JF, Wang Z. et al. A numerical and experimental study of internal solitary wave loads on semi-submersible platforms. Ocean Engineering, 2018,150:298-308
[9]	Duan JL, Chen K, You YX. et al. Numerical investigation of vortex-induced vibration of a riser with internal flow. Applied Ocean Research, 2018,72:110-121
[10]	Zhang XH, Lu XB, Shi YH. et al. Study on the mechanical properties of hydrate-bearing silty clay. Marine and Petroleum Geology, 2015,67:72-80
[11]	Zhang XH, Lu XB, Chen XD. et al. Mechanism of soil stratum instability induced byhydrate dissociation. Ocean Engineering, 2016,122:74-83
[12]	Zhang XH, Lu XB, Xiao M. Gas outburst with sediments because of tetrahydrofuran hydrate dissociation. International Journal for Numerical & Analytical Methods in Geomechanics, 2015,39(17):1884-1897
[13]	刘林, 姚仰平, 张旭辉等. 含水合物沉积物的弹塑性本构模型. 力学学报, 2020,52(2):556-566 (Liu Lin, Yao Yangping, Zhang Xuhui, et al. An elastoplastic constitutive model for gas hydrate-bearing sediments. Chinese Journal of Theoretical and Applied Mechanics. 2020,52(2):556-566 (in Chinese))
[14]	杨柳, 石富坤, 张旭辉等. 含水合物粉质黏土压裂成缝特征实验研究. 力学学报, 2020,52(1):224-234 (Yang Liu, Shi Fukun, Zhang Xuhui, et al. Experimental studies on the propagation characteristics of hydraulic fracture in clay hydrate sediment. Chinese Journal of Theoretical and Applied Mechanics. 2020,52(1):224-234 (in Chinese))
[15]	Kang Q, Wang J, Duan L. et al. The volume ratio effect on flow patterns and transition processes of thermocapillary convection. Journal of Fluid Mechanics, 2019,868:560-583
[16]	Kang Q, Wu D, Duan L. et al. Surface configurations and wave patterns of thermocapillary convection onboard the SJ10 satellite. Physics of Fluids, 2019,31(4):044105
[17]	Kang Q, Wu D, Duan L. et al. The effects of geometry and heating rate on thermocapillary convection in the liquid bridge. Journal of Fluid Mechanics, 2019,881:951-982
[18]	Kang Q, Wu D, Duan L. et al. Space experimental study on wave modes under instability of thermocapillary convection in liquid bridges on Tiangong-2. Physics of Fluids, 2020,32(3):034107
[19]	Zhao JF. Two-phase flow and pool boiling heat transfer in microgravity. International Journal of Multiphase Flow, 2010,36(2):135-143
[20]	吴克, 赵建福, 李会雄. 微重力池沸腾过程中的气泡热动力学特征研究. 力学与实践, 2016,38(2):203-206 (Wu Ke, Zhao Jianfu, Li Huixiong. Thermal dynamical behavior of vapor bubble during pool boiling in microgravity. Mechanics in Engineering. 2016,38(2):203-206 (in Chinese))
[21]	Feng Y, Li HX, Guo KK. et al. Numerical study on saturated pool boiling heat transfer in presence of a uniform electric field using lattice Boltzmann method. International Journal of Heat and Mass Transfer, 2019,135:885-896
[22]	Li ZD, Zhang L, Zhao JF. et al. Numerical simulation of bubble dynamics and heat transfer with transient thermal response of solid wall during pool boiling of FC-72. International Journal of Heat & Mass Transfer, 2015,84:409-418
[23]	杜王芳, 赵建福. 核态池沸腾传热现象中的重力标度规律. 科学通报, 2020,65(17):9-17 (Du Wangfang, Zhao Jianfu. Gravity scaling law of heat transfer in nucleate pool boiling. Chinese Science Bulletin. 2020,65(17):1629-1637 (in Chinese))
[24]	Li WB, Lan D, Wang YR. Exploration of Direct-Ink-Write 3D Printing in space: droplet dynamics and patterns formation in microgravity. Microgravity Science and Technology, 2020,32(5):935-940
[25]	Li WB, Ji WJ, Sun HH. et al. Pattern formation in drying sessile and pendant droplet: interactions of gravity settling, interface shrinkage, and capillary flow. Langmuir: the ACS journal of surfaces and colloids, 2019,35(1):113-119
[26]	Li WB, Ji WJ, Lan D. et al. Self-assembly of ordered microparticle monolayers from drying a droplet on a liquid substrate. The Journal of Physical Chemistry Letters, 2019,10(20):6184-6188
[27]	Li WB, Lan D, Sun HH. et al. Drop capturing based on patterned substrate in space. Langmuir: the ACS journal of surfaces and colloids, 2018,34(16):4715-4721
[28]	Ni MJ, Munipalli R, Huang P. et al. A current density conservative scheme for incompressible MHD flows at a low magnetic Reynolds number. Part II: On an arbitrary collocated mesh. Journal of Computational Physics, 2007,227(1):205-228
[29]	Chen L, Li MJ, Ni MJ. et al. MHD effects and heat transfer analysis in magneto-thermo-fluid-structure coupled field in DCLL blanket. International Communications in Heat and Mass Transfer, 2017,84:110-120
[30]	Chen L, Smolentsev S, Ni MJ. Toward full simulations for a liquid metal blanket: MHD flow computations for a PbLi blanket prototype at Ha, $sim$ ,10 $^{4}$ . Nuclear Fusion, 2020,60(7):076003
[31]	陈松, 孙泉华. 高超声速飞行流场中的最大氧离解度分析. 力学学报, 2014,46(1):20-27 (Chen Song, Sun Quanhua. Analysis of maximum dissociation degree of oxygen during hypersonic flight. Chinese Journal of Theoretical and Applied Mechani. 2014,46(1):20-27 (in Chinese))
[32]	洪启臻, 王小永, 孙泉华. 高温非平衡流动中的氧分子振动态精细分析. 力学学报, 2019,51(6):1761-1774 (Hong Qizhen, Wang Xiaoyong, Sun Quanhua. Detailed analysis of vibrational states of oxygen in high temperature non-equilibrium flows. Chinese Journal of Theoretical and Applied Mechanics. 2019,51(6):1761-1774 (in Chinese))
[33]	Ding JC, Si T, Yang JM. et al. Measurement of a Richtmyer-Meshkov Instability at an Air-SF $_{6}$ Interface in a Semiannular Shock Tube. Physical Review Letters, 2017,119(1):014501
[34]	Si T, Long T, Zhai ZG. et al. Experimental investigation of cylindrical converging shock waves interacting with a polygonal heavy gas cylinder. Journal of Fluid Mechanics, 2015,784:225-251
[35]	丛洲洋, 郭旭, 司廷. 反射激波诱导界面不稳定性研究进展. 中国科学: 物理学力学天文学, 2020,50(10):18-39 (Cong Zhouyang, Guo Xu, Si Ting. Advances in interfacial instability induced by reshock. Scientia Sinica Physica, Mechanica & Astronomica, 2020,50:104703 (in Chinese))
[36]	丁举春, 翟志刚, 司廷等. 汇聚Richtmyer-Meshkov 不稳定性实验研究进展. 科学通报, 2018,63:618-628 (Ding Juchun, Zhai Zhigang, Si Ting, et al. Progress in experiments of converging Richtmyer-Meshkov instability. Chinese Scencei Buletinl. 2018,63:618-628 (in Chinese))
[37]	罗喜胜, 翟志刚, 司廷等. 激波诱导下的气体界面不稳定性实验研究. 力学进展, 2014,44(1):201407-201407 (Luo Xisheng, Zhai Zhigang, Si Ting, et al. Experimental study on the interfacial instability induced by shock waves. Advances in Mechanics. 2014,44(1):201407 (in Chinese))
[38]	Wang C, Han ZY, Situ M. Investigation of high-speed combustible gas ignited by a hot gas jet produced in the shock tube. Shock Waves, 2006,15(2):129-135
[39]	司徒明, 王春, 陆惠萍. 双燃式冲压发动机中富油燃气射流的超燃研究. 推进技术, 2001,22(3):237-240 (Situ Ming, Wang Chun, Lu Huiping. Investigation on supersonic combustion of fuel-rich hot gas as reacting jets in ramjet/scramjet combustor. Journal of Propulsion Technology. 2001,22(3):237-240 (in Chinese))
[40]	Wang C, Jiang ZL, Hu ZM. et al. Numerical investigation on the flowfield of "swallowtail" cavity for supersonic mixing enhancement. Acta Mechanica Sinica, 2009,25(1):37-44
[41]	Pan ZW, Huang SH, Su Y. et al. Strain field measurements over 3000 $^circ$ C using 3D-Digital image correlation. Optics and Lasers in Engineering, 2019,127:105942
[42]	Pan ZW, Huang SH, Jiang ML. In-situ measurements of deformation to fatigue failure on a flat-type divertor mockup under high heat flux loads by 3D digital image correlation. Nuclear Fusion, 2020
[43]	Huang SH, Liu SM. Numerical analysis of fatigue behavior of ITER-Like monoblock divertor interlayer under coupled heat loads. Journal of Fusion Energy, 2018,37(4):177-186
[44]	黄生洪, 乐吴生. 一种金属表面形成微纳米多层次复合结构的加工工艺. 2017-7-17, 中国: CN201710580981. 5
[45]	黄生洪, 郑智风. 一种超高等静压静温环境生成装置及方法. 2017-3-13, 中国: CN201710145588. 3
[46]	Luo J, Wang ZH. Analogy between vibrational and chemical nonequilibrium effects on stagnation flows. AIAA Journal, 2020,58(5):2156-2164
[47]	Wang ZH, Yu YL, Bao L. Heat transfer in nonequilibrium flows with homogeneous and heterogeneous recombination reactions. AIAA Journal, 2018,56(9):3593-3599
[48]	Yu YL, Li XD, Wang ZH. et al. Theoretical modeling of heat transfer to flat plate under vibrational excitation freestream conditions. International Journal of Heat and Mass Transfer, 2020,151:119434
[49]	Wang ZH. Generalized hypersonic equivalence principle. AIAA Journal, 2020,58(1):255-264
[50]	李一鸣, 李祝飞, 杨基明等. 典型高超声速内转式进气道激光散射流场显示. 航空学报, 2017,38(12):121414 (Li Yiming, Li Zhufei, Yang Jiming, et al. Flow visulalization of a typical hypersonic inward-turning inlet using laser scattering. Acta Aeronautica et Astronautica Sinica. 2017,38(12):121414 (in Chinese))
[51]	Xiao FS, Li ZF, Zhang ZY. et al. Hypersonic shock wave interactions on a v-shaped blunt leading edge. AIAA Journal, 2018,56(1):356-367
[52]	Zhang ZY, Li ZF, Huang R. et al. Experimental investigation of shock oscillations on V-shaped blunt leading edges. Physics of Fluids, 2019,31(2):026110
[53]	Li ZF, Zhang ZY, Wang J. Pressure--heat flux correlations for shock interactions on v-shaped blunt leading edges. AIAA Journal, 2019,57(10):356-367
[54]	Wang J, Li ZF, Zhang ZY. et al. Shock interactions on v-shaped blunt leading edges with various conic crotches. AIAA Journal, 2019,58(3):1407-1411
[55]	Zhang F, Si T, Zhai ZG. et al. Reflection of cylindrical converging shock wave over a plane wedge. Physics of Fluids, 2016,28(8):086101
[56]	Wang H, Zhai ZG, Luo XS. et al. A specially curved wedge for eliminating wedge angle effect in unsteady shock reflection. Physics of Fluids, 2017,29(8):086103
[57]	Han G, Jiang Z. Approximate analytic solution of heat conduction in hollow semi-spheres flying at hypersonic speed. International Communications in Heat & Mass Transfer, 2013,43:46-52
[58]	Meng BQ, Han GL, Yuan CK. et al. Experimental and numerical study on hypersonic flow over double-wedge configuration. AIAA Journal, 2017,55(9):3227-3230
[59]	Meng BQ, Han GL, Zhang DL. et al. Aerodynamic measurement of a large aircraft model in hypersonic flow. Chinese Physics B, 2017,26(11):114702
[60]	姜宗林, 李进平, 胡宗民等. 高超声速飞行复现风洞理论与方法. 力学学报, 2018,50(6):1283-1291 (Jiang Zonglin, Li Jinping, Hu Zongmin, et al. Shock tunnel theory and methods for duplicating hypersonic flight conditions. Chinese Journal of Theoretical and Applied Mechanics. 2018,50(6):1283-1291 (in Chinese))
[61]	孟宝清, 韩桂来, 姜宗林. 结构振动对大型激波风洞气动力测量的干扰. 力学学报, 2016,48(1):102-110 (Meng Baoqing, Han Guilai, Jiang Zonglin. Theoretical investigation on aerodynamic force measurement interfered by structural vibrations in large shock tunnel. Chinese Journal of Theoretical and Applied Mechanics. 2016,48(1):102-110 (in Chinese))

[1]	Yuan Hao, Kou Jiaqing, Zhang Weiwei. RESEARCH PROGRESS OF RESOLVENT ANALYSIS IN FLUID MECHANICS[J]. Chinese Journal of Theoretical and Applied Mechanics, 2024, 56(10): 2799-2814. DOI: 10.6052/0459-1879-24-223
[2]	Han Fang, Wang Qingyun. RESEARCH ADVANCES AND SOME THOUGHTS ON NEURODYNAMICS[J]. Chinese Journal of Theoretical and Applied Mechanics, 2023, 55(4): 805-813. DOI: 10.6052/0459-1879-22-404
[3]	Wang Gengxiang, Ma Daolin, Liu Yang, Liu Caishan. RESEARCH PROGRESS OF CONTACT FORCE MODELS IN THE COLLISION MECHANICS OF MULTIBODY SYSTEM[J]. Chinese Journal of Theoretical and Applied Mechanics, 2022, 54(12): 3239-3266. DOI: 10.6052/0459-1879-22-266
[4]	Zhang Qingdian, Ma Hongwei, Yang Yi, Xiao Anqi. PROGRESS AND PROSPECT OF AERODYNAMIC EXPERIMENTAL RESEARCH ON LINEAR CASCADE[J]. Chinese Journal of Theoretical and Applied Mechanics, 2022, 54(7): 1755-1777. DOI: 10.6052/0459-1879-21-684
[5]	Song Wei, Ai Bangcheng. RESEARCH PROGRESS ON MULTIBODY AERODYNAMICS[J]. Chinese Journal of Theoretical and Applied Mechanics, 2022, 54(6): 1461-1484. DOI: 10.6052/0459-1879-22-096
[6]	Yan Jun, Hu Haitao, Su Qi, Yin Yuanchao, Wu Shanghua, Lu Hailong, Lu Qingzhen. PROSPECT AND PROGRESSION OF KEY MECHANICAL PROBLEMS IN MARINE CABLES[J]. Chinese Journal of Theoretical and Applied Mechanics, 2022, 54(4): 846-861. DOI: 10.6052/0459-1879-22-113
[7]	Chen Shijiang, Zhu Wancheng, Wang Chuangye, Zhang Fei. REVIEW OF RESEARCH PROGRESSES OF THE QUANTIFYING JOINT ROUGHNESS COEFFICIENT[J]. Chinese Journal of Theoretical and Applied Mechanics, 2017, 49(2): 239-256. DOI: 10.6052/0459-1879-16-255
[8]	Mei Fengxiang, Wu Huibiny, Li Yanmin, Chen Xiangwei. ADVANCES IN RESEARCH ON BIRKHOFFIAN MECHANICS[J]. Chinese Journal of Theoretical and Applied Mechanics, 2016, 48(2): 263-268. DOI: 10.6052/0459-1879-15-193
[9]	Zhu Jianguo, Xie Huimin, Liu Zhanwei. RESEARCH PROGRESS ON THE EXPERIMENTAL MEASUREMENT METHODS OF MECHANICAL PROPERTIES OF THERMAL BARRIER COATINGS[J]. Chinese Journal of Theoretical and Applied Mechanics, 2013, 45(1): 45-60. DOI: 10.6052/0459-1879-12-080
[10]	Li Jianjun, Zhao Yapu. RESEARCH PROGRESS ON KINETICS OF CELL SPREADING[J]. Chinese Journal of Theoretical and Applied Mechanics, 2012, 44(5): 807-823. DOI: 10.6052/0459-1879-12-104

Cited By

Cited by

Periodical cited type(1)

刘莉，王利行，张正. 航空航天飞行器热端部件用高温材料极端环境力学性能测试标准分析及展望. 居业. 2023(09): 185-189 .

Other cited types(0)

Get Citation

PDF

XML

Article Metrics

Article views (1218) PDF downloads (461) Cited by(1)

NEW PROGRESS IN THE FIELD OF EXTRAORDINARY ENVIRONMENTAL MECHANICS——REVIEW OF THE CHINESE JOURNAL OF THEORETICAL AND APPLIED MECHANICS SYMPOSIUM ON EXTREME MECHANICS

Abstract

References

Related Articles

Cited by

Periodical cited type(1)

Other cited types(0)

Catalog

Article Metrics

Related

Download Center

Author Center

NEW PROGRESS IN THE FIELD OF EXTRAORDINARY ENVIRONMENTAL MECHANICS——REVIEW OF THE CHINESE JOURNAL OF THEORETICAL AND APPLIED MECHANICS SYMPOSIUM ON EXTREME MECHANICS

Abstract

References

Related Articles

Cited by

Periodical cited type(1)

Other cited types(0)

Catalog

Article Metrics

Related

Download Center

Author Center

Export File

Citation

Format

Content